Recombination at Prunus S-locus region SLFL1 gene

In Prunus, the self-incompatibility (S-) locus region is <70 kb. Two genes-the S-RNase, which encodes the functional female recognition component, and the SFB gene, which encodes the pollen recognition component-must co-evolve as a genetic unit to maintain functional incompatibility. Therefore, recombination must be severely repressed at the S-locus. Levels of recombination at genes in the vicinity of the S-locus have not yet been rigorously tested; thus it is unknown whether recombination is also severely repressed at these loci. In this work, we looked at variability levels and patterns at the Prunus spinosa SLFL1 gene, which is physically close to the S-RNase gene. Our results suggest that the recombination level increases near the SLFL1 coding region. These findings are discussed in the context of theoretical models predicting an effect of linked weakly deleterious mutations on the relatedness of S-locus specificities. Moreover, we show that SLFL1 belongs to a gene family of at least five functional genes and that SLFL1 pseudogenes are frequently found in the S-locus region.     

The alternative splice variant of DAPK-1, s-DAPK-1, induces proteasome-independent DAPK-1 destabilization

Death-associated protein kinase 1 (DAPK-1) is a Ca²⁺/CaM-regulated kinase involved in multiple cellular signalling pathways that trigger cell survival, apoptosis, and autophagy. An alternatively spliced product expressed from the dapk1 locus, named s-DAPK-1, does not contain the kinase domain but has part of the DAPK-1 ankyrin-repeat and a novel polypeptide tail extension which is processed proteolytically in vivo. Cleavage of this polypeptide tail from s-DAPK-1 can regulate the ability of the protein to mimic one of the biological functions of DAPK-1 in promoting membrane blebbing. The full-length DAPK-1 protein is a relatively long-lived protein whose half-life is regulated by stress-activated signals from TNFR1 or HSP90 that can promote DAPK-1 protein degradation. Transfection of s-DAPK-1 into cells can also have a direct effect on DAPK-1 protein itself by promoting DAPK-1 de-stabilization. This effect does not require the novel polypeptide tail-extension of s-DAPK-1, as the core ankyrin-repeat containing region of s-DAPK-1 is sufficient to promote DAPK-1 protein de-stabilization. Conversely, the minimal domain on full-length DAPK-1 that responds to the effect of s-DAPK-1 is not the ankyrin-repeat domain but the core kinase domain of DAPK-1. The de-stabilization of DAPK-1 by s-DAPK-1 is not dependent upon the proteasome. However, s-DAPK-1 itself is a very short-lived protein which is regulated by a proteasomal-dependent pathway. Together, these data identify a novel function of s-DAPK-1 in controlling the half-life of DAPK-1 protein itself and indicate that the degradation of each gene product is controlled by two distinct degradation pathways.     

Leucyl-tRNA Synthetase-dependent and -independent Activation of a Group I Intron

Leucyl-tRNA synthetase (LeuRS) is an essential RNA splicing factor for yeast mitochondrial introns. Intracellular experiments have suggested that it works in collaboration with a maturase that is encoded within the bI4 intron. RNA deletion mutants of the large bI4 intron were constructed to identify a competently folded intron for biochemical analysis. The minimized bI4 intron was active in RNA splicing and contrasts with previous proposals that the canonical core of the bI4 intron is deficient for catalysis. The activity of the minimized bI4 intron was enhanced in vitro by the presence of the bI4 maturase or LeuRS.Although the aminoacyl-tRNA synthetases (aaRSs)⁶ are best known for their role in protein synthesis, many have functionally expanded and are essential to a wide range of other cellular activities that are unrelated to tRNA aminoacylation (1). The class I aaRSs, leucyl- (LeuRS or NAM2) and tyrosyl-tRNA synthetase (TyrRS or CYT-18) are required for RNA splicing of cognate group I introns in the mitochondria of certain lower eukaryotes (2). In yeast, processing of two related group I introns called bI4 and aI4α (Fig. 1) from the cob and cox1α genes, respectively, require yeast mitochondrial LeuRS (3, 4). Likewise, expression of Neurospora crassa mitochondrial genes, such as those for the large ribosomal RNA, is dependent on TyrRS for excising group I introns (5).Open in a separate windowFIGURE 1.Predicted secondary structures of the bI4 and aI4α group I introns. The secondary structure of the canonical core was based on previous predictions (19). Solid bold lines indicate linear connectivities of the nucleic acid strand with arrowheads oriented in the 5′ to 3′ direction. The dashed lines represent putative tertiary interactions. Dotted lines with numbers identify insertions where secondary structures were ambiguous. Arrows in the P1 and P9 domain show splice sites, whereas boxed nucleotides are paired regions.LeuRS facilitates RNA splicing in concert with a bI4 maturase that is encoded within the bI4 intron. Genetic investigations showed that an inactivated bI4 maturase resulting in deficient splicing activity of the bI4 and aI4α group I introns can be rescued by a suppressor mutation of LeuRS to restore mitochondrial respiration (4, 6). In addition, the splicing defect can be compensated by a mutant aI4α DNA endonuclease that is closely related to the bI4 maturase (7, 8).Previously, we used intracellular three-hybrid assays to demonstrate that LeuRS and bI4 maturase can independently bind to the bI4 intron and stimulate RNA splicing activity in the non-physiological yeast nucleus compartment (9). RNA-dependent two-hybrid assays also supported that the bI4 intron could simultaneously bind both the bI4 maturase and LeuRS. In this case, the RNA was co-expressed with LeuRS and bI4 maturase that was fused to either LexA or B42 to generate a two-hybrid response. This suggested that the bI4 intron was bridging these two protein splicing factors. In either the RNA-dependent two-hybrid or three-hybrid assays, bI4 intron splicing occurred only in the presence of LeuRS or bI4 maturase or both.We hypothesized that the bI4 maturase and LeuRS bind to distinct sites of the bI4 intron to form a ternary complex and promote efficient splicing activity. However, the functional basis of the collaboration between these two splicing cofactors or how either of them promotes RNA splicing remains unclear.We sought to characterize the respective splicing roles of the bI4 maturase and LeuRS via biochemical investigations. Previous attempts to develop an in vitro splicing assay for the bI4 intron or its closely related aI4α intron have failed (10, 11). It was hypothesized that the long length of the bI4 intron (∼1600 nucleotides) and its highly A:U-rich content (∼80%) hindered RNA folding in vitro as well as stabilization of its competent structure.Efforts to produce an active form of the bI4 intron have relied on building chimeric group I introns by interchanging RNA domains with the more stable Tetrahymena thermophila group I intron (11). Based on these results, it was proposed that the catalytic core of the bI4 group I intron was inherently defective (11). In this case, the group I intron would be expected to be completely dependent on its protein splicing factors similar to the bI3 intron that relies on the bI3 maturase and Mrs1 for activity (12). Thus, it was hypothesized that the bI4 maturase and/or LeuRS splicing factors aided the bI4 group I intron by targeting its core region to compensate for these deficiencies.We focused our efforts on re-designing the bI4 intron to develop a minimized molecule that might be competent for splicing. Because both the bI4 and aI4α group I introns rely on the bI4 maturase and LeuRS for their splicing activity, we compared their secondary structures to identify and eliminate peripheral regions outside of their catalytic cores. A small active derivative of the bI4 intron, comprised of just 380 nucleotides primarily from the canonical core, was generated. Thus, we show that, in and of itself, the canonical core of this group I intron is competent for splicing. Both the bI4 maturase and LeuRS enhance the splicing activity of the minimized bI4 intron. However, it is possible that protein-dependent splicing of the bI4 intron represents an intermediate evolutionary step in which the RNA activity is becoming increasingly dependent on its protein splicing factors.     

CytokineDB: a database collecting biological information

Cytokines are subdivided in 12 sub-families and are described as multi-functional molecules that play an important biological activity in host defense system against pathogens, in homeostasis, tissue repair, cell growth and development. CytokineDB is an annotated database that collects biological information regarding the cytokines family in human and will be periodically updated by including new biological information. This database is freely available online and can be accessed at the URL: http://www.cro-m.eu/CytokineDB/     

Human Papillomavirus Type 16 (HPV-16) Virus-Like Particle L1-Specific CD8+ Cytotoxic T Lymphocytes (CTLs) Are Equally Effective as E7-Specific CD8+ CTLs in Killing Autologous HPV-16-Positive Tumor Cells in Cervical Cancer Patients: Implications for L1 Dendritic Cell-Based Therapeutic Vaccines

Papillomavirus-like particles (VLPs) based on L1 capsid protein represent a promising prophylactic vaccine against human papillomavirus (HPV) infections. However, cell-mediated immune responses against this antigen are believed to be of limited therapeutic value in established HPV-infected cervical lesions and, for this reason, have not been intensively investigated in cervical cancer patients. In this study we analyzed and quantified by real-time PCR (RT-PCR) the RNA expression levels of E6, E7, and L1 genes in flash-frozen HPV-16 cervical carcinomas. In addition, the kinetics of expression of E6, E7, and L1 in HPV-16-infected primary cell lines established as long-term cultures in vitro was also evaluated at RNA and protein levels. Finally, in order to evaluate the therapeutic potential of L1-specific CD4⁺ and CD8⁺ T lymphocytes responses in cervical cancer patients, L1 VLP-loaded dendritic cells (DCs) were used to stimulate peripheral blood lymphocytes from cervical cancer patients and such responses were compared to those elicited by the E7 oncoprotein. We show that 22 of 22 (100%) flash-frozen cervical biopsy samples collected from HPV-16-positive cervical cancer patients harbor L1, in addition to E6 and E7 RNA, as detected by RT-PCR. E7 RNA copy number (mean, 176.2) was significantly higher in HPV-16-positive cervical cancers compared to the E6 RNA copy number (mean, 47.3) and the L1 copy number (mean, 58.3) (P < 0.0001 and P < 0.001, respectively). However, no significant differences in expression levels between E6 and L1 were found. Kinetic studies of E6, E7, and L1 RNA and protein expression levels in primary tumors showed a sharp reduction in L1 expression after multiple in vitro passages compared to E6 and E7. Autologous DCs pulsed with HPV-16 VLPs or recombinant full-length E7 elicited strong type 1 L1- and E7-specific responses in CD4⁺ and CD8⁺ T cells from cervical cancer patients. Importantly, L1 VLP-specific CD8⁺ T lymphocytes expressed strong cytolytic activity against autologous tumor cells and were as effective as E7-specific cytotoxic T lymphocytes in lysing naturally HPV-16-infected autologous tumor cells. Taken together, these data demonstrate a consistent expression of L1 in primary cervical tumors and the possibility of inducing effective L1/tumor-specific CD4⁺ and CD8⁺ T-lymphocyte responses in patients harboring HPV-infected cervical cancer. These results may have important implications for the treatment of patients harboring established HPV-infected lesions with L1 VLPs or combined E7/L1 DC-based vaccinations.Human papillomavirus (HPV) infection represents the most important risk factor for the development of cervical cancer. Although more than 100 distinct HPV genotypes have been described, and at least 20 are associated with cervical cancer, HPV type 16 (HPV-16) is by far the most frequently detected in cervical neoplasia regardless of the geographical origin of the patients (4). In the last few years significant advances have been made in the development of candidate prophylactic vaccine against cervical cancer and HPV-related infections. In several large prospective randomized studies, virus-like particles consisting of the HPV-16 and HPV-18 major capsid protein L1 (L1-VLPs) have shown promise in protecting young healthy females against persistent infection with HPV-16 and HPV-18 and their associated cervical intraepithelial neoplasia (reviewed in reference 12). These data strongly suggest that the implementation of large-scale L1-VLP-based prophylactic vaccinations have the potential to dramatically reduce worldwide cervical cancer rates in the years to come.Unfortunately, because HPV infection is endemic in humans and there is a long latency from HPV infection to the development of invasive cervical cancer in women, even if prophylactic L1-based vaccinations are implemented on a worldwide scale today it would take decades to perceive any significant benefit. Consistent with this view, an estimated 5 million cervical cancer deaths will occur in the next 20 years due to existing HPV infections (4, 12). Thus, the current development of therapeutic vaccines for protection against persistent HPV infections, cervical cancer, and its precursor lesions remains an area of great interest.Although the interactions between the host immune system and HPV-infected cells are still not completely understood, several lines of evidence suggest that protection against HPV-related infections by L1-VLP-based vaccines is likely conferred by the generation of high levels of neutralizing antibodies (12, 38). Nevertheless, a potential crucial role of L1-specific T-cell responses and the involvement of T cells in mediating the production of neutralizing antibodies and antiviral effect in infected hosts has been previously hypothesized (8, 24). This point may be particularly noteworthy in patients harboring HPV-infected cervical lesions because several studies have demonstrated the critical importance of both cytotoxic (CD8⁺) and helper (CD4⁺) T cells in achieving clinical responses (1, 5, 16-18, 20, 23). However, limited information is currently available to evaluate whether cell-mediated immune responses to L1-VLP may have any significant therapeutic effect in cervical cancer patients harboring HPV-16 positive tumors. Furthermore, to our knowledge, no direct comparison of the therapeutic efficacy of L1 and E7-specific immune responses against naturally HPV-16-infected cervical cancer have been yet reported in human patients.In the present study we have analyzed and quantified by highly sensitive real-time PCR (RT-PCR) the RNA levels of E6, E7, and L1 in flash-frozen biopsy specimens obtained from HPV-16-infected cervical carcinomas and in short- and long-term primary cultures of HPV-16-positive cervical tumors. In addition, we have studied the kinetics of expression of these genes and proteins during the establishment of HPV-16-positive primary tumors in vitro. Finally, using completely autologous systems of naturally infected HPV-16-positive human tumors, we have carefully studied the phenotype and function of L1-specific CD4⁺ and CD8⁺ T-lymphocyte responses generated by VLP-loaded dendritic cells (DCs) and compared their therapeutic potential to those elicited by DC loaded with the E7 oncoprotein.     

Molecular and cytogenetic characterization of an AT-rich satellite DNA family in <Emphasis Type="Italic">Urvillea chacoensis</Emphasis> Hunz. (Paullinieae,Sapindaceae)

Urvillea chacoensis is a climber with 2n = 22 and some terminal AT-rich heterochromatin blocks that differentiate it from other species of the genus. The AT-rich highly repeated satellite DNA was isolated from U. chacoensis by the digestion of total nuclear DNA with HindIII and XbaI and cloned in Escherichia coli. Satellite DNA structure and chromosomal distribution were investigated. DNA sequencing revealed that the repeat length of satDNA ranges between 721 and 728 bp, the percentage of AT-base pairs was about 72–73% and the studied clones showed an identity of 92.5–95.9%. Although this monomer has a tetranucleosomal size, direct imperfect repetitions of ~180 bp subdividing it in four nucleosomal subregions were observed. The results obtained with FISH indicate that this monomer usually appears distributed in the terminal regions of most chromosomes and is associated to heterochromatin blocks observed after DAPI staining. These observations are discussed in relation to the satellite DNA evolution and compared with other features observed in several plant groups.     

Ancestral Origin of the ATTCT Repeat Expansion in Spinocerebellar Ataxia Type 10 (SCA10)

Spinocerebellar ataxia type 10 (SCA10) is an autosomal dominant neurodegenerative disease characterized by cerebellar ataxia and seizures. The disease is caused by a large ATTCT repeat expansion in the ATXN10 gene. The first families reported with SCA10 were of Mexican origin, but the disease was soon after described in Brazilian families of mixed Portuguese and Amerindian ancestry. The origin of the SCA10 expansion and a possible founder effect that would account for its geographical distribution have been the source of speculation over the last years. To unravel the mutational origin and spread of the SCA10 expansion, we performed an extensive haplotype study, using closely linked STR markers and intragenic SNPs, in families from Brazil and Mexico. Our results showed (1) a shared disease haplotype for all Brazilian and one of the Mexican families, and (2) closely-related haplotypes for the additional SCA10 Mexican families; (3) little or null genetic distance in small normal alleles of different repeat sizes, from the same SNP lineage, indicating that they are being originated by a single step mechanism; and (4) a shared haplotype for pure and interrupted expanded alleles, pointing to a gene conversion model for its generation. In conclusion, we show evidence for an ancestral common origin for SCA10 in Latin America, which might have arisen in an ancestral Amerindian population and later have been spread into the mixed populations of Mexico and Brazil.